U.S. patent number 5,649,457 [Application Number 08/413,767] was granted by the patent office on 1997-07-22 for park lock arrangement for continuously variable transmission.
This patent grant is currently assigned to Aichi Machine Industry Co., Ltd., Nissan Motor Co., Ltd.. Invention is credited to Kiyoshi Kudou, Hirofumi Okahara, Toshio Yamaguchi.
United States Patent |
5,649,457 |
Kudou , et al. |
July 22, 1997 |
Park lock arrangement for continuously variable transmission
Abstract
A park lock arrangement for use in a continuously variable
transmission including a housing, an end cover and a casing having
one end portion coupled with the housing and the opposite end
portion coupled with the end cover. The casing has an inwardly
recessed portion to define a reduced container space. A follower
shaft supporting a follower pulley has one end portion rotatably
supported on the end cover and the opposite end portion extending
into the housing. A driver gear is mounted on the opposite end
portion of the follower shaft. A parking gear is disposed on the
follower shaft between the follower pulley and the driver gear. A
control shaft extends through the reduced container space and has
one end portion projecting outwardly from the inwardly recessed
portion of the casing. The control shaft drivingly supports a park
lock mechanism for locking the parking gear. The park lock
mechanism is disposed within the reduced container space.
Inventors: |
Kudou; Kiyoshi (Nagoya,
JP), Yamaguchi; Toshio (Hadano, JP),
Okahara; Hirofumi (Isehara, JP) |
Assignee: |
Nissan Motor Co., Ltd.
(Yokohama, JP)
Aichi Machine Industry Co., Ltd. (Nagoya,
JP)
|
Family
ID: |
13909297 |
Appl.
No.: |
08/413,767 |
Filed: |
March 30, 1995 |
Foreign Application Priority Data
|
|
|
|
|
Apr 4, 1994 [JP] |
|
|
6-087240 |
|
Current U.S.
Class: |
74/606R; 475/210;
74/577R |
Current CPC
Class: |
F16H
63/3416 (20130101); B60T 1/005 (20130101); F16H
61/36 (20130101); Y10T 74/2136 (20150115); Y10T
74/2186 (20150115) |
Current International
Class: |
F16H
63/48 (20060101); B60T 1/00 (20060101); F16H
63/00 (20060101); B60K 041/26 () |
Field of
Search: |
;74/500.5,51.5R,575,577R,577M,66R ;475/210 ;474/8,28 |
References Cited
[Referenced By]
U.S. Patent Documents
Other References
"Nissan Technical Handbook, March K11-1", Nissan Motor Co., Ltd.,
1992..
|
Primary Examiner: Marmor; Charles A.
Assistant Examiner: Battista; Mary Ann
Attorney, Agent or Firm: Foley & Lardner
Claims
What is claimed is:
1. A park lock arrangement for use in a continuously variable
transmission, comprising:
a housing;
an end cover;
a casing having one end portion coupled with the housing and an
opposite end portion coupled with the end cover, the casing having
an inwardly recessed portion defining a reduced container
space;
a rotatable shaft extending through the housing, the casing, and
the end cover;
a parking gear disposed on the rotatable shaft;
a park lock mechanism for locking the parking gear disposed within
the reduced container space;
a control shaft rotatably disposed at the one end portion of the
casing and drivingly supporting the park lock mechanism, the
control shaft having one end portion projecting outwardly from the
casing through the reduced container space; and
a cable connected to the control shaft,
wherein the casing is formed with a cable guide portion connected
to the inwardly recessed portion.
2. A park lock arrangement according to claim 1, wherein the
control shaft is located at a front portion of the casing.
3. A park lock arrangement according to claim 1, further comprising
a control valve body secured to the casing and supporting an
opposite end portion of the control shaft.
4. A park lock arrangement according to claim 1, wherein the park
lock mechanism includes a pawl adapted to engage the parking gear,
and an actuator operatively connected to the pawl.
5. A park lock arrangement according to claim 4, further comprising
a pulley mounted on the rotatable shaft, the pulley including a
cylindrical portion with a reduced diameter radially opposed to the
cable guide portion.
6. A park lock arrangement for use in a continuously variable
transmission, comprising:
a housing;
an end cover;
a casing having one end portion coupled with the housing and an
opposite end portion coupled with the end cover, the casing having
an inwardly recessed portion defining a first reduced container
space inside the casing and a mounting space outside the
casing;
a direction change planetary gearing having an input shaft;
a driver shaft coaxial with the input shaft;
a follower shaft extending parallel to the driver shaft, the
follower shaft having one end portion rotatably supported on the
end cover, an intermediate portion rotatably supported on the
casing, and an opposite end portion extending into the housing;
a continuously variable ratio change unit including a driver pulley
mounted on the driver shaft, a follower pulley mounted on the
follower shaft, and a V-belt interconnecting the driver pulley and
the follower pulley;
a differential;
a gear train drivingly disposed between the continuously variable
ratio change unit and the differential, the gear train including a
driver gear mounted on the opposite end portion of the follower
shaft;
a parking gear disposed on the follower shaft between the follower
pulley and the driver gear;
a park lock mechanism for locking the parking gear;
a control shaft extending through the first reduced container space
and drivingly supporting the park lock mechanism, the control shaft
having one end portion projecting outwardly from the inwardly
recessed portion of the casing and disposed in the mounting space;
and
a cable connected to the control shaft,
wherein the driver shaft and the park lock mechanism are disposed
within the first reduced container space, and wherein the casing is
formed with a cable guide portion connected to the inwardly
recessed portion.
7. A park lock arrangement according to claim 6, wherein the casing
defines a second container space adjacent the first reduced
container space in which the follower shaft, the gear train, and
the differential are partly disposed.
8. A park lock arrangement according to claim 6, wherein the park
lock mechanism includes a pawl arranged to be engageable with the
parking gear, and an actuator operatively connected to the
pawl.
9. A park lock arrangement according to claim 6, wherein the
control shaft is disposed at the one end portion of the casing.
10. A park lock arrangement according to claim 6, wherein the cable
is disposed in the mounting space.
11. A park lock arrangement according to claim 6, further
comprising a control valve body secured to the casing and
supporting an opposite end portion of the control shaft.
12. A park lock arrangement according to claim 6, wherein the
follower pulley includes a cylindrical portion with a reduced
diameter radially opposed to the cable guide portion.
Description
RELATED COPENDING APPLICATION
U.S. patent application Ser. No. 08/187,286 filed by Yoshiyasu
MURAKAMI et al. on Jan. 27, 1994, now U.S. Pat. No. 5,480,361.
BACKGROUND OF THE INVENTION
The present invention relates to a park lock arrangement for use in
a continuously variable transmission.
A publication entitled "NISSAN TECHNICAL HANDBOOK, MARCH K11-1,
January, 1992" discloses a park lock arrangement for use in a
continuously variable transmission. This known arrangement includes
a housing, an end cover, and a casing coupled with the housing and
the end cover at the opposite end portions. The known arrangement
includes a direction change planetary gearing having an input
shaft, and a continuously variable ratio change unit including a
driver pulley mounted on a driver shaft coaxial with the input
shaft. A follower shaft extends in parallel with the driver shaft
and has one end portion rotatably supported on the end cover, the
opposite end portion extending into the housing, and an
intermediate portion therebetween. A follower pulley is disposed on
the intermediate portion close to the one end portion of the
follower shaft. A V-belt interconnects the driver and follower
pulleys. A gear train is drivingly disposed between the
continuously variable ratio change unit and a differential. A
parking gear is formed integrally with the follower pulley and thus
located closer to the one end portion of the follower shaft. A park
lock mechanism is so arranged in the vicinity of the parking gear
as to lock the parking gear. The park lock mechanism includes a
pawl arranged to be engageable with the parking gear, an actuator
operatively connected to the pawl, and a control shaft linked with
the actuator and rotatably supported on the casing.
In such a prior art park lock arrangement, an assembling operation
of the park lock mechanism should be conducted simultaneously with
or in advance of a coupling operation of the casing with the end
cover. In addition, since the parking gear formed integrally with
the follower pulley has a relatively large diameter, it is required
to provide a sufficiently large mounting space for the park lock
mechanism within a vehicle body.
There is a demand for a park lock arrangement for use in a
continuously variable transmission in which an assembling operation
of the park lock mechanism can be carried out readily and
separately from a coupling operation of the casing with the end
cover.
An object of the present invention is to provide an improved park
lock arrangement for use in a continuously variable transmission,
which arrangement serves for an easy assembling operation.
Another object of the present invention is to provide a
space-saving structure of the park lock arrangement for use in the
continuously variable transmission, thereby serving to reduce
size.
SUMMARY OF THE INVENTION
According to one aspect of the present invention, there is provided
a park lock arrangement for use in a continuously variable
transmission, comprising:
a housing;
an end cover;
a casing having one end portion coupled with the housing and the
opposite end portion coupled with the end cover, the casing having
an inwardly recessed portion to define a first reduced container
space;
a direction change planetary gearing having an input shaft;
a driver shaft coaxial with the input shaft of the change direction
planetary gearing;
a follower shaft extending in parallel relationship with respect to
the driver shaft, the follower shaft having one end portion
rotatably supported on the end cover, an intermediate portion
rotatably supported on the casing, and the opposite end portion
extending into the housing;
a continuously variable ratio change unit including a driver pulley
mounted on the driver shaft, a follower pulley mounted on the
follower shaft, and a V-belt interconnecting the driver pulley and
the follower pulley;
a differential;
a gear train drivingly disposed between the continuously variable
ratio change unit and the differential, the gear train including a
driver gear mounted on the opposite end portion of the follower
shaft;
a parking gear disposed on the follower shaft between the follower
pulley and the driver gear;
a park lock mechanism for locking the parking gear; and
a control shaft drivingly supporting the park lock mechanism, the
control shaft extending through the first reduced container space
and having one end portion projecting outwardly from the inwardly
recessed portion of the casing;
the driver shaft and the park lock mechanism being disposed within
the first reduced container space.
According to another aspect of the present invention, there is
provided a park lock arrangement for use in a continuously variable
transmission, comprising:
a housing;
an end cover;
a casing having one end portion coupled with the housing and the
opposite end portion coupled with the end cover;
a rotatable shaft extending through the housing, the casing and the
end cover;
a parking gear mounted on the rotatable shaft;
a park lock mechanism for locking the parking gear; and
a control shaft drivingly supporting the park lock mechanism;
the control shaft being rotatably disposed at the one end portion
of the casing, the control shaft extending through the casing and
having one end portion projecting outwardly from the casing.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a diagrammatic section of a continuously variable
transmission taken along one end portion of a casing at which the
casing is coupled with a housing, showing a preferred embodiment of
a park lock arrangement according to the present invention;
FIG. 2 is a development view taken along the line 2--2 of FIG.
1;
FIG. 3 is a fragmentary section taken along the line 3--3 of FIG.
1;
FIG. 4 is an enlarged view taken along the line 4--4 of FIG. 1;
FIG. 5 is a fragmentary section taken along the line 5--5 of FIG.
1; and
FIG. 6 is a fragmentary section of a change direction planetary
gearing of the continuously variable transmission.
DETAILED DESCRIPTION OF THE INVENTION
Referring to FIG. 2, there is shown a continuously variable
transmission for a vehicle.
As illustrated in FIG. 2, the continuously variable transmission
includes a hydrokinetic torque transmitting unit in the form of a
torque converter 300, a continuously variable ratio change unit
302, and a direction change planetary gearing 303 disposed between
the torque converter 300 and the continuously variable ratio change
unit 302. A converter housing 306 accommodates the torque converter
300. A casing 10 has one end portion coupled with the converter
housing 306 and the opposite end portion coupled with an end cover
304. The casing 10 serves, not only as a container for the
component parts of the planetary gearing 303, but also as a
container for the continuously variable ratio change unit 302 in
cooperation with the end cover 304. In cooperation with the
converter housing 306, the casing 10 serves as a container for a
differential 308 and a gear train 310 drivingly disposed between
the continuously variable ratio change unit 302 and the
differential 308.
The direction change planetary gearing 303 within the casing 10 is
adapted to change-over forward and reverse directions. The
planetary gearing 303 will be described later in detail.
As viewed in FIG. 2, the planetary gearing 303 has an input shaft
32 extending through a stationary sleeve 90. The input shaft 32 is
splined at its righthand end to a turbine runner 314 of the torque
converter 300. The torque converter 300 includes, in addition to
the turbine runner 314, a pump impeller 316 drivingly connected to
an engine crankshaft 318, a stator 320, and a lock-up piston 322.
In the conventional manner, the pump impeller 316 is drivingly
connected to a pump housed in a pump cover 324. The pump cover 324
includes the stationary sleeve 90.
The planetary gearing 303 has an output shaft 18 coaxial with the
input shaft 32. As viewed in FIG. 2, the output shaft 18 has its
righthand end portion rotatably supported by a ball bearing 16 on
the casing 10 and its lefthand end portion rotatably supported by a
ball bearing 326 on the end cover 304, and extends into the end
cover 304. The output shaft 18 serves as a driver shaft.
A follower shaft 342 extends in parallel relationship with respect
to the driver shaft 18. As viewed in FIG. 2, the follower shaft 342
has one lefthand end portion rotatably supported by a ball bearing
344 on the end cover 304, an intermediate portion rotatably
supported by a ball bearing 346 on the casing 10, and the opposite
righthand end portion extending beyond the ball bearing 346 further
into the converter housing 306. Thus, the follower shaft 342
extends through the converter housing 306, the casing 10 and the
end cover 304. Fixedly mounted on the opposite end portion or third
portion is a driver gear 348 of the gear train 310.
The continuously variable ratio change unit 302 includes a driver
pulley 328 mounted on the driver shaft 18, a follower pulley 330
mounted on the intermediate portion of the follower shaft 342, and
a V-belt 332 interconnecting the driver and follower pulleys 328
and 330. The driver pulley 328 includes an axially stationary
conical disc 334 integral with and extending radially outwardly
from the driver shaft 18, and an axially moveable conical disc 336
slidably mounted on the driver shaft 18. The axially moveable
conical disc 336 is mounted for rotation with the driver shaft 18
and arranged in opposed relationship with the axially stationary
conical disc 334 and defines a V-shaped pulley groove. The axially
moveable conical disc 336 is displaceable in axial direction of the
driver shaft 18 in response to an increase in fluid pressure within
a driver pulley servo chamber 338 from a first limit position as
illustrated by the fully drawn line in FIG. 2 to a second limit
position as illustrated by the phantom line in FIG. 2. The follower
pulley 330 includes an axially stationary conical disc 340 integral
with and radially extending outwardly from the follower shaft 342.
The follower pulley 330 includes, in addition to the axially
stationary conical disc 340, an axially moveable conical disc 350.
The axially moveable conical disc 350 is slidably mounted on the
follower shaft 342 although it is mounted for rotation with the
follower shaft 342. The axially moveable conical disc 350 is
arranged in opposed relationship with the axially stationary
conical disc 340 to define a V-shaped groove. The axially moveable
conical disc 350 is biased towards the axially stationary conical
disc 340 in response to fluid pressure within a follower pulley
servo chamber 352. The V-belt 332 is gripped between the conical
discs 340 and 350 with a force proportional to load on the engine
and speed ratio accomplished by the driver and follower pulleys 328
and 330. The fluid pressure within the follower pulley servo
chamber 340 is variable with the engine load and the speed ratio.
When the axially moveable conical disc 336 of the driver pulley 328
assumes the first position as illustrated by the fully drawn line
in FIG. 2, the axially moveable conical disc 350 of the follower
pulley 330 stays in a position as illustrated by the fully drawn
line in FIG. 2. Increasing the fluid pressure within the driver
pulley servo chamber 338 causes the axially moveable conical disc
336 to move toward the second position as illustrated by the
phantom line in FIG. 2. This movement of the conical disc 336
causes the V-belt 332 to move radially outwardly from the driver
shaft 18 and radially inwardly toward the follower shaft 342. This
radially inward movement of the V-belt 332 causes the V-belt 332 to
separate the axially moveable conical disc 350 from the axially
stationary conical disc 340. Thus, owing to the tension of the
V-belt 332, the axially moveable conical discs 336 and 350 move
from the position as illustrated by the fully drawn line in FIG. 2
toward the position as illustrated by the phantom line in FIG.
2.
The gear train 310 includes, in addition to the driver gear 348, an
idler gear 354 integral with an idler shaft 356, and a pinion 358
rotatable with the idler shaft 356. The idler shaft 356 extends in
parallel relationship with the follower shaft 342 and it is
rotatably supported by two taper roller bearings 360 and 362. The
taper bearings 360 and 362 are mounted on the casing 10 and the
converter housing 306, respectively. The driver gear 348 meshes the
idler gear 354. Thus, rotation of the follower shaft 342 causes the
pinion 358 to rotate. The pinion 358 meshes with a final gear
364.
The differential 308 includes, in addition to the final gear 364, a
differential casing 366 rotatable with the final gear 364, a pinion
shaft 368 rotatable with the differential casing 366, a pair of
pinions 370 rotatably supported by the pinion shaft 368, and a pair
of side gears 372 meshing the pinions 370. Reference numeral 380
denotes left and right axle shafts splined to the side gears
372.
As shown in FIG. 2, a parking gear 400 is fixedly disposed on the
follower shaft 342 between the driver gear 348 and the follower
pulley 330. Specifically, the parking gear 400 is interposed
between the ball bearing 346 and the driver gear 348. Thus, the
parking gear 400 is axially spaced from the follower pulley 300 and
located in the vicinity of the one end portion of the casing 10 at
which the casing 10 is coupled with the converter housing 306. The
parking gear 400 has a smaller diameter than the follower pulley
330, as seen in FIG. 2.
Referring to FIGS. 1, 3 and 4, there is shown a park lock mechanism
for locking the parking gear 400 and a control shaft 424 drivingly
supporting the park lock mechanism. As illustrated in FIG. 1, the
park lock mechanism includes a pawl 402 adapted to engage the
parking gear 400. The pawl 402 is pivoted to the casing 10 by a pin
404 shown in FIG. 3. The pawl 402 has a tooth 406 engageable with a
gap between adjacent two teeth of the parking gear 400 and a cam
follower portion 408 kept in contact with a cam member 414 of an
actuator 410. The pawl 402 is biased by a spring 412 shown in FIG.
3, in such a direction, clockwise as viewed in FIG. 1, as to be
contacted at the cam follower portion 408 with the cam member 414
of the actuator 410. The cam member 414 is of a generally funnel
shape having a first cam surface 414A on an increased diameter
annular portion thereof and a second cam surface 414B on a reduced
diameter annular portion thereof. The cam member 414 is disposed
within a cylindrical guide 416 which has at its upper portion as
viewed in FIG. 1, a cutout for allowing a contact between the cam
member 414 and the cam follower portion 408 of the pawl 402. The
cam member 414 is connected with a parking lever 418 through a rod
420. The rod 420 has a hooked end portion extending downwardly as
viewed in FIG. 1, at which the rod 420 is inserted into an opening
422 of a tapered end portion of the parking lever 418 such that the
rod 420 is oscillated with respect to the parking lever 418. The
parking lever 418 has an enlarged end portion, shown in FIG. 3,
secured to an upper portion as viewed in FIG. 1, of the control
shaft 424. The control shaft 424 is rotatably supported by the
casing 10. Thus, the cam member 414 is reciprocally moved in the
cylindrical guide 416 in response to a unitary rotation of the
control shaft 424 and the parking lever 418. When the control shaft
424 rotates in such a direction that the first cam surface 414A of
the cam member 414 engages the cam follower portion 408 of the pawl
402, the pawl 402 is forced to rotate counterclockwise as viewed in
FIG. 1 and then engages the parking gear 400. When the control
shaft 424 rotates in the opposite direction, the second cam surface
414B of the cam member 414 engages the cam follower portion 408 of
the pawl 402. The pawl 402 is forced to rotate clockwise as viewed
in FIG. 1 so that the pawl 402 disengages from the parking gear
400.
The control shaft 424 is located at the one end portion of the
casing 10 at which the casing 10 is coupled with the converter
housing 306, and at a front portion of the casing 10 as seen in
FIG. 1. The control shaft 424 has one or upper end portion as
viewed in FIG. 1, rotatably supported by the casing 10 and projects
outwardly from the casing 10. The control shaft 424 extends through
the inside of the casing 10 and has the opposite or lower end
portion as viewed in FIG. 1, rotatably supported by a manual
control valve body 426, which is secured to a bottom of the casing
10. The control shaft 424 extends generally vertically relative to
the valve body 426. The opposite or lower end portion of the
control shaft 424 is connected with a lever 428 to actuate a valve
spool in the valve body 426. A control lever 430 is fixed to the
one end portion of the control shaft 424, which projects outwardly
from the casing 10. As shown in FIGS. 1 and 4, a cable 432 is
pivotally connected with the control lever 430 at one end thereof.
The cable 432 is connected at the other end thereof to a shift
lever disposed in an occupant's compartment and moveable in
response a movement of the shift lever. The movement of the shift
lever causes a unitary rotation of the control lever 430 and the
control shaft 424. Reference numeral 434 denotes an inhibitor
switch disposed below the control lever 430.
As illustrated in FIG. 1, the casing 10 has an inwardly recessed
portion 436 to define a first reduced container space S1. The input
shaft 32 of the planetary gearing 303, the driver shaft 18 coaxial
therewith, and the park lock mechanism are disposed within the
first reduced container space S1. The casing 10 defines a second
container space S2 adjacent the first reduced container space S1 in
which the follower shaft 342 and the gear train 310 and the
differential 308 are partly disposed. The inwardly recessed portion
436 defines a mounting space S3 outside the casing 10. Reference B
denotes a part of a vehicle body. As viewed in FIG. 1, the mounting
space S3 extends from an upper surface of the inwardly recessed
portion 436 upwardly substantially up to the uppermost level of the
casing 10. The first container space S1 and the mounting space S3
are disposed at the front portion of the casing 10 and the second
container space S2 is disposed at a rear portion of the casing 10.
The driver shaft 18 and the input shaft 32 are arranged within the
casing 10 more downwardly as viewed in FIG. 1, than the follower
shaft 342 and the idler shaft 356. The control shaft 424 extends
through the first reduced container space S1 and the one or upper
end portion thereof projects outwardly from the inwardly recessed
portion 436. The park lock mechanism, including the pawl 402 and
actuator 410, are disposed at an upper part, as viewed in FIG. 1,
of the first reduced container space S1, in opposed relationship
with the inwardly recessed portion 436 of the casing 10. This
arrangement serves for saving a mounting space for the park lock
mechanism. The projecting end portion of the control shaft 424, the
control lever 430, the pivoted end portion of the cable 432, and
the inhibitor switch 434 are disposed on the inwardly recessed
portion 436 of the casing 10 and thus within the mounting space S3.
This arrangement contributes to space-saving and prevents
interference of these components with other components disposed
thereabove.
As illustrated in FIG. 5, a cable guide portion 438 in the form of
a groove is disposed on an outer surface of the casing 10 and
connected to the inwardly recessed portion 436. A portion of the
cable 432 extending beyond the inwardly recessed portion 436 toward
the shift lever is received in the cable guide portion 438. The
cable guide portion 438 is radially opposed to a cylindrical
portion 440 of the follower pulley 330 formed integrally with the
axially moveable conical disc 350 and has a reduced diameter.
As will be understood from the preceding description, the park lock
arrangement of the invention serves for an easy assembling
operation.
It should be noted that the parking gear 400 may be reduced in
diameter as compared with the parking gear used in the prior art
park lock arrangement formed integrally with the follower pulley
with a larger diameter. This reduction of the parking gear diameter
contributes to saving of a mounting space for the park lock
mechanism.
The direction change planetary gearing 303 shown in FIG. 6 is
substantially the same as described in a copending U.S. Pat.
application Ser. No. 08/187,286 filed on Jan. 27, 1994 which is
hereby incorporated by reference. Reference is made to FIG. 1 of
this Patent Application and the corresponding descriptive part in
understanding the detail of the mechanism of the planetary
gearing.
Referring to FIG. 6, the casing 10 includes a partition 12 formed
with a ball bearing receiving bore 14. Received in this bore 14 is
the ball bearing 16 rotatably supporting the output shaft 18. The
ball bearing 16 includes an outer race 20 and an inner race 22. The
outer race 20 is in engagement with the bore 14 defining a wall and
held in position within the bore 14 by means of a snap ring 24 in
the conventional manner. The inner race 22 is in engagement with
the output shaft 18 in the conventional manner. As viewed in FIG.
6, the output shaft 18 includes a central boss 26 projecting from
the righthand axial end thereof. The central boss 26 is formed with
a bore 28 for rotatably receiving a reduced diameter end portion 30
of the input shaft 32. The central boss 26 is externally splined at
34 for spline connection with a sun gear 36.
The partition 12 is recessed at a portion radially outwardly spaced
from the ball bearing receiving bore 14 to define a cylindrical
shoulder 38 and a cylindrical inner wall portion 40. The
cylindrical inner wall portion 40 is radially spaced from the
cylindrical shoulder 38 to define an annular bore 42 is an annular
disc portion 44 of a piston 46 of a reverse brake 48. The annular
disc portion 44 has an outer periphery in seal-tight engagement
with the cylindrical inner wall portion 40 and an inner periphery
in seal-tight engagement with the cylindrical shoulder 38, and
defines within the annular bore 42 a brake servo chamber 50.
Communicating with this servo chamber 50 is a supply passage 52
drilled through the casing 10. The piston 46 includes, in addition
to the annular disc portion 44, a plurality of angularly spaced arm
portions, only one being shown at 54 in FIG. 6, and a plurality of
angularly spaced spring retainer boss portions, only one being
shown at 56 in FIG. 6. The arm portions 54 and spring retainer boss
portions 56 are alternatively arranged along the outer periphery of
the annular disc portion 44 and projects in parallel and in a
direction away from the partition 12. The arm portions 54 extend
further than the spring retainer boss portions 56 do. The reverse
brake 48 also includes a plurality of return springs, only one
being shown at 58 in FIG. 6, and a return spring retainer 60
fixedly mounted to the casing 10 by means of a snap ring 62. The
return springs 58 are disposed between the return spring retainer
60 and the corresponding spring retainer boss portions 56 to bias
the piston 46 toward a spring set position thereof as illustrated
in FIG. 6.
As shown in FIG. 6, the reverse brake 48 includes a cylindrical
portion 64. The cylindrical portion 64 is disposed radially
inwardly with respect to the arm portions 54 of the piston 46 and
radially opposed to a cylindrical inner wall portion 68 defined by
the casing 10. This cylindrical inner wall portion 68 is splined to
engage a plurality of driven frictional plates 70 by spline
connection. The cylindrical portion 64 is splined to engage a
plurality of driver frictional plates 72. The driver and driven
frictional plates 70 and 72 are interleaved to form a reverse brake
frictional plate assembly 74. The reverse brake frictional plate
assembly 74 includes, in addition to the driver and driven
frictional plates 70 and 72, a retaining plate 76 and a dish plate
78. The retaining plate 76 is spline connected to the cylindrical
inner wall portion 68 and held by a snap ring 80. The dish plate 78
is disposed between the leading ends of the arm portions 54 and the
adjacent one driven frictional plate 70.
Received in the cylindrical portion 64 is a clutch drum 82 of a
forward clutch 83. The clutch drum 82 includes an outer cylindrical
portion 84, an inner cylindrical portion 86 and an annular end
portion 88 interconnecting the outer and inner cylindrical portions
84 and 86. The inner cylindrical portion 86 is coaxially arranged
with respect to the input shaft 32. The input shaft 32 extends
through the stationary sleeve 90 and has a radially protruded
portion 92. The radially protruded portion 92 is axially spaced
From the adjacent axial end of the stationary sleeve 90. The
radially protruded portion 92 is formed with a cutout 94 to receive
a flange portion 96 extending radially inwardly from the axial end
of the inner cylindrical portion 86. The clutch drum 82 is fixedly
connected to the input shaft 32 for rotation therewith by welding
the inner cylindrical portion 86 to the radially protruded portion
92.
Defined by the outer and inner cylindrical portions 84 and 86 and
annular end portion 88 is an annular bore 98 slidably receiving an
annular clutch piston 100. The clutch piston 100 has an outer
periphery in seal-tight engagement with the outer cylindrical
portion 84 and an inner periphery in seal-tight engagement with the
inner cylindrical portion 86, and defines within the annular bore
98 a clutch servo chamber 102. A return spring retainer 104 is
coupled with the inner cylindrical portion 86 and held by a snap
ring 106. A plurality of return springs 108 are disposed between
the return spring retainer 104 and the clutch piston 100 to bias
the piston 100 towards a spring set position thereof as illustrated
in FIG. 6.
The outer cylindrical portion 84 is splined axially inwardly from
the leading end thereof to engage externally splined driver
frictional plates 112 by spline connection. Disposed radially
inwardly of the outer cylindrical portion 84 is a cylindrical
portion 114 of a hub 116. The cylindrical portion 114 is splined to
engage a plurality of driven frictional plates 118 by spline
connection. The driver and driven frictional plates 112 and 118 are
interleaved to form a forward clutch frictional plate assembly 120.
The forward clutch frictional plate assembly 120 includes, in
addition to the driver and driven frictional plates 112 and 118, a
retaining plate 122 and a dish plate 124. The retaining plate 122
is spline connected to the outer cylindrical portion 84 and held by
a snap ring 126. The dish plate 124 is disposed between the clutch
piston 100 and the adjacent one of the driver frictional plates
112.
An internally toothed ring gear 128 of a planetary gear set 130 is
externally splined to engage the outer cylindrical portion 84 by
spline connection. The ring gear 128 is axially fit to the outer
cylindrical portion 84 by a snap ring 132.
The planetary gear set 130 includes, in addition to the sun and
ring gears 36 and 128, a pinion carrier 134. The pinion carrier 134
includes a plurality of pinion shafts or spindles 136 and a
plurality of pinions 140 rotatably carried by the plurality of
spindles 136, respectively. Each of the plurality of pinions 140
meshes the sun and ring gears 36 and 128. All of the spindles 136
are fixedly mounted to a radially extending annular disc portion
142. This annular disc portion 142 has an outer periphery
integrally connected to the cylindrical portion 64 and an inner
periphery 144. The annular disc portion 142 merges smoothly into
the cylindrical portion 64.
As will be readily seen from FIG. 6, the planetary gear set 130 is
received in the cylindrical portion 64 and has its ring gear 128
connected to the clutch drum 82 and its pinion carrier 134
connected to the cylindrical portion 64.
As mentioned before, the central boss 28 is spline connected to the
sun gear 36. For spline connection to the central boss 26, the sun
gear 36 is formed with a splined bore 146 engaging the central boss
26 and an enlarged bore 148 surrounding the reduced diameter end
portion 30 of the input shaft 32. The sun gear 36 includes an
axially protruding portion 150 defining the enlarged bore 148. The
axially protruding portion 150 is formed with an outer peripheral
cutout 152 receiving an inner peripheral portion 154 of the hub
116. The axially protruding portion 150 is formed with an inner
peripheral cutout 156 receiving a thrust bearing 158. The thrust
bearing 158 is disposed between and in rolling contact with the
radially protruded portion 92 of the input shaft 32 and the sun
gear 36. Disposed between the radially protruded portion 92 and the
stationaary sleeve 90 is a thrust bearing 160.
The hub 116, fixedly connected to the sun gear 36 and integral with
the cylindrical portion 114, extends in such a manner as to define
on the lefthand side, viewing in FIG. 6, adjacent to the pinions
140 a radially extending clearance space 162. On the opposite
righthand side, viewing in FIG. 6, the hub 116 defines a space 164
within the clutch drum 82.
As shown in FIG. 6, the radially extending annular disc portion 142
of the pinion carrier 134 is interposed between the ball bearing
inner race 22 and the sun gear 36. The sun gear 36 is formed with a
recessed portion 166 and includes a radially extending bottom wall
168 partially defining the recessed portion 166. The radially
extending annular disc portion 142 is offset at a portion radially
spaced from the inner periphery 144 thereof to form an axially
displaced inner peripheral portion 170. The axially displaced inner
peripheral portion 170 defines on the righthand side, viewing in
FIG. 6, a first radially extending wall 172 opposed to the radially
extending bottom wall 168 of the recessed portion 166. On the
opposite lefthand side, the axially displaced inner peripheral
portion 170 defines a second radially extending wall 174 opposed to
a radially extending wall 176 of the ball bearing inner race 22.
Two thrust bearings, namely a first thrust bearing 178 and a second
thrust bearing 180, are so disposed as to prevent mechanical
interference between the radially extending annular disc portion
142, partition 12 of the casing 10 and sun gear 36.
Specifically, the first thrust bearing 178 is disposed between and
in rolling contact with the radially extending bottom wall 168 and
the radially extending wall 172 of the axially displaced inner
peripheral portion 170, while the second thrust bearing 180 is
disposed between and in rolling contact with the radially extending
wall 174 of the axially displaced inner peripheral portion 170 and
the radially extending wall 176 of the ball bearing inner race
22.
It should be noted that the recessed portion 166 and the axially
displaced inner peripheral portion 170 allow compact arrangement of
the thrust bearings 178 and 180 with a clearance between the
partition 12 and the radially extending annular disc portion 142
kept minimum. This arrangement contributes much to reduction in
axial span or dimension, with respect to the axis of the input
shaft 32, of the planetary gearing 303.
Lubrication system for the planetary gearing 303 is now described.
The stationary sleeve 90 is formed with a lubrication oil supply
passage 182, which is supplied with lubrication oil under pressure.
This supply passage 182 is provided with an outlet orifice 184 at a
location adjacent to the thrust bearing 160. The radially protruded
portion 92 of the input shaft 32 is formed with a plurality of
angularly spaced axial lubrication oil passages 186. These axial
passages 186 establish fluid communication between an annular space
188 defined between the radially protruded portion 92 and the
stationary sleeve 90 and an annular chamber 190 defined within the
enlarged bore 148. The sun gear 36 is formed with a plurality of
axial lubrication oil passages 192. Each of the axial passages 192
has one end opening to the annular chamber 190 and the opposite end
opening within the radially extending bottom wall 168 of the
recessed portion 166 of the sun gear 36. Via these lubrication oil
passages 186 and 192, the thrust bearings 158, 178 and 180 are
supplied with lubrication oil. The thrust bearing 160 is supplied
with lubrication oil at a portion immediately downstream of the
orifice 184 of the supply passage 182.
The axially protruding portion 150 of the sun gear 36 is formed
with a plurality of radial oil lubrication passages 194. Each of
the radial passages 194 has a radially inward inlet end opening to
the annular chamber 190 and a radially outward outlet end opening
to the radially extending clearance space 162. With these radial
passages 194, lubrication oil is thrown radially outwardly towards
the clutch frictional plate assembly 120 during rotation of the
input shaft 32. This lubrication passage arrangement assures
sufficient supply of lubrication oil to the clutch frictional plate
assembly 120.
In order to assure sufficient supply of lubrication oil to the
space 164 within the clutch drum 82, a plurality of axial ports 196
are drilled through the axially protruding portion 150 of the sun
gear 36. These axial ports 196 establish fluid communication at
least some of the plurality of radial passages 194 and the space
164 within the clutch drum 82.
* * * * *